Bend-limited flexible optical interconnect device for signal distribution

ABSTRACT

The invention relates to a bend limiting structure for preventing a flexible optical circuit from being bent too sharply. More particularly, the invention involves adding a bend limiting layer or layers to the flexible optical circuit and/or any housing or other structure within which it is enclosed or to which it is attached. The bend-limiting layer may comprise a plurality of blocks arranged in a line or plane and joined by a flexible film that is thinner than the blocks, with the blocks positioned close enough to each other so that, if that plane of blocks is bent a predetermined amount, the edges of the blocks will interfere with each other and prevent the plane from being bent any further. The blocks may be resilient also to provide a less abrupt bend-limiting stop.

CROSS REFERENCE TO RELATED APPLICATION

This is a continuation of U.S. application Ser. No. 14/987,021, filedJan. 4, 2016, which is a continuation of U.S. application Ser. No.13/230,117, filed Sep. 12, 2011, now U.S. Pat. No. 9,229,172, thedisclosures of which are incorporated herein by reference in theirentireties.

FIELD OF THE INVENTION

The invention pertains to fiber optic connectivity for high speed signaldistribution. More particularly, the invention pertains to methods andapparatus for bend limiting a flexible optical interconnect device.

BACKGROUND OF THE INVENTION

Fiber optic breakout cassettes are merely one form of passive opticalinterconnect devices commonly used for distributing signals between oneor more transmit optical components and one or more receive opticalcomponents (often in opposite directions simultaneously).

Other common passive optical interconnect devices are opticalmultiplexers and demultiplexers, which comprise a flexible opticalcircuit, for distributing signals between one or more single- ormulti-fiber optical connectors on the one hand and one or more single-or multi-fiber optical connectors on the other hand. Other common formsof optical interconnect include simple patch cables and opticalsplitters.

Flexible optical circuits are passive optical components that compriseone or more (typically multiple) optical fibers imbedded on a flexiblesubstrate, such as a Mylar® or other flexible polymer substrate.Commonly, although not necessarily, one end face of each fiber isdisposed adjacent one longitudinal end of the flexible optical circuitsubstrate and the other end face of each fiber is disposed adjacent theopposite longitudinal end of the flexible optical circuit substrate. Thefibers extend past the longitudinal ends of the flexible optical circuit(commonly referred to as pigtails) so that they can be terminated tooptical connectors, which can be coupled to fiber optic cables or otherfiber optic components through mating optical connectors.

Flexible optical circuits are known, and hence, will not be described indetail. However, they essentially comprise one or more fibers sandwichedbetween two flexible sheets of material, such as Mylar® or anotherpolymer. An epoxy may be included between the two sheets in order tomake them adhere to each other. Alternately, depending on the sheetmaterial and other factors, the two sheets may be heated above theirmelting point to heat weld them together with the fibers embeddedbetween the two sheets.

FIG. 1, for example, shows a flexible optical circuit 100 that might beused in an optical multiplexer/demultiplexer. This flexible opticalcircuit 100 commonly is referred to as a shuffle. FIG. 2 shows acomplete optical multiplexer/demultiplexer 200 including the shuffle 100and a housing 102. The top of the housing is removed in FIG. 2 to allowviewing of the internal components of the device 200. This particularoptical multiplexer/demultiplexer 200 is intended to distribute signalsbetween a set of eight multi-fiber optical cables 201 on the right sideof the figure, each containing eight fibers (not shown), and another setof eight optical cables 203 on the left side of the figure, each cablecontaining eight fibers (not shown). More particularly, the cables 201and 203 terminate to suitable optical connectors 207 and 209,respectively, which engage with mating connectors 211, 213,respectively, through adapters 215, 217 disposed in the housing 102. Foreach of the eight right-hand cables 201, the fibers 105 embedded in theshuffle 100 break out the eight signal paths and distribute one each toeach of the eight left-hand cables 203, and vice versa.

Flexible optical circuits such as shuffle 100 of FIGS. 1 and 2 can bebent too sharply. Particularly, there are three concerns with respect tobending flexible optical circuits too sharply. First, the optical fibers105 embedded within them can break if bent too sharply. Secondly, evenif the fibers do not break, too sharp of a bend in a fiber can causelight to escape from the core of the fiber, thus leading to signal loss.Finally, the flexible optical circuit substrate usually is a laminate,and bending a laminate too sharply can cause it to de-laminate.

SUMMARY OF THE INVENTION

The invention relates to a bend limiting structure for preventing aflexible optical circuit from being bent too sharply. More particularly,the invention involves adding a bend limiting layer or layers to theflexible optical circuit and/or any housing or other structure withinwhich it is enclosed or to which it is attached. The bend-limiting layermay comprise a plurality of blocks arranged in a line or plane andjoined by a flexible film that is thinner than the blocks, with theblocks positioned close enough to each other so that, if that plane ofblocks is bent a predetermined amount, the edges of the blocks willinterfere with each other and prevent the plane from being bent anyfurther. The blocks may be resilient also to provide a less abruptbend-limiting stop.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a flexible optical circuit of the priorart.

FIG. 2 shows an optical multiplexer/de multiplexer incorporating theflexible optical circuit of FIG. 1.

FIG. 3 is a top perspective view of a lensed flexible optical circuit inaccordance with the principles of the present invention.

FIG. 4 shows an optical cassette in accordance with the principles ofthe present invention comprising a housing and incorporating theflexible optical circuit of FIG. 3.

FIG. 5 shows another optical cassette housing for housing a flexibleoptical circuit in accordance with the principles of the presentinvention.

FIG. 6 shows yet another optical cassette housing for housing a flexibleoptical circuit in accordance with the principles of the presentinvention.

FIG. 7 is a bottom perspective view of a lensed flexible optical circuitthat can replace the flexible optical circuit and internal connectors ofFIG. 3.

FIG. 8A is a sectional side view of the lensed flexible optical circuitof FIG. 3 through section 8A shown in FIG. 7.

FIG. 8B is a sectional side view of the lensed flexible optical circuitof FIG. 3 through section 8B shown in FIG. 7.

FIG. 9 is a side view of the lensed flexible optical circuit of FIGS.3-5 bent to its limit in one dimension.

FIG. 10 is a cross-sectional side view of a bend limiting layer inaccordance with an alternate embodiment of the invention.

FIG. 11 shows the housing of FIG. 7 including a pair of bend limitinglayers in accordance with the principles of the present invention.

DETAILED DESCRIPTION

U.S. Patent Publication No. 2013/0064506, filed Sep. 12, 2011, which isincorporated herein fully by reference, discloses a lensed flexibleoptical circuit bearing at least one, but, more effectively, manyoptical fibers embedded in a flexible optical circuit substrate withmolded lenses (or other light-guiding, fiber termination elements suchas mirrors, gratings, etc.) disposed at the ends of the fibers. Thelensed flexible optical circuit can be incorporated into a housing toform any number of optical interconnect devices, such as opticalcassettes, optical multiplexers/demultiplexers, optical breakouts, andoptical monitoring stations. The lenses can be optically interfaced tooptical connectors (e.g., MPO, LC, ST, SC plugs) at the ends of cablesor at the interfaces of electro-optical devices without the need for afull mating connector (e.g., MPO, LC, ST, SC receptacles). Rather, aconnector on an optical component, e.g., an LC plug at the end of afiber optic cable, can be plugged into an adapter on a panel of thehousing to optically couple to one of the optical fibers on the flexibleoptical circuit inside of the cassette enclosure via one of the lenses.The elimination of conventional mating connectors inside the cassettesignificantly reduces overall cost because it eliminates the skilledlabor normally associated with terminating an optical fiber to aconnector, including polishing the end face of the fiber and epoxyingthe fiber into the connector. It further allows the optical interconnectdevice (e.g., an optical cassette) to be made very thin. The housing forthe lensed flexible optical circuit also may be flexible. In yet otherembodiments, there may be no housing at all.

Since the lensed flexible optical circuit is mechanically flexible, theconcept of the present invention can be used in many differentapplications, of which optical cassettes is merely one example. Forinstance, it can be used to make right angle connections. It may becurled into a cylinder and used to make optical interconnections inexisting conduit. The lensed flexible optical circuit connectivityconcept can be incorporated into flexible housings, such as housingsmade of rubber so that a single cassette can be used to make connectionsin different environments and/or can compensate for offsets in all sixdegrees of freedom (e.g., X, Y, Z, roll, pitch, and yaw).

The invention further can be incorporated into housings having partsinterconnected by one or more hinges so that the housings are bendableabout the hinges to provide similar flexibility.

FIG. 3 show a top perspective view of such a lensed flexible opticalcircuit 250 configured as an optical breakout circuit incorporating theprinciples of the present invention. Particularly, an optical fibercable (not shown) on the right hand side containing twelve fibers (e.g.,six transmit fibers and six receive fibers) is routed in pairs (onereceive and one transmit) to six, dual-fiber optical cables (not shown)on the left hand side. Thus, the flexible optical circuit 250 includestwelve optical fibers 217 routed accordingly. All of the embedded fibers217 are terminated at each end to lens blocks 257 containing moldedlenses 230.

Considerable technology has been developed relating to the design,fabrication, and use of such lenses in optical connectors, whichtechnology can be used to design and fabricate such lenses 230,terminate the optical fibers 217 with such lenses, and couple lightthrough such lenses to fibers in optical connectors. Such informationcan be obtained from the following patents and patent applications, allof which are incorporated herein fully by reference:

U.S. Pat. No. 7,722,261 entitled Expanded Beam Connector;

U.S. Pat. No. 8,085,472 entitled Expanded Beam Interface Device andMethod of Fabricating Same;

U.S. Pat. No. 8,313,249 entitled Multi-Fiber Ferrules for MakingPhysical Contact and Method of Determining Same;

U.S. Pat. No. 6,012,852 entitled Expanded Beam Fiber Optic Connector;

U.S. Pat. No. 6,208,779 entitled Optical Fiber Array Interconnection;

U.S. Pat. No. 6,480,661 entitled Optical ADD/DROP Filter and Method ofMaking Same;

U.S. Pat. No. 6,690,862 entitled Optical Fiber Circuit;

U.S. Pat. No. 6,012,852 entitled Expanded Beam Fiber Optic Connector;and

U.S. Patent Publication No. 2012/0014645, filed Jul. 14, 2010, entitledSingle-Lens, Multi-Fiber Optical Connector Method and Apparatus.

More specifically, technology is available to couple a connectordirectly in front of the lens 230 so that the lens does not need to haveits own conventional mating connector, such as disclosed inaforementioned U.S. Pat. No. 7,722,261.

As shown in FIG. 4, such a lensed flexible optical circuit 250 may bedisposed within a housing or other structure with adaptors or otherstructure for receiving external connectors at the ends of cables 105 oron other optical components so as to optically couple with the lenses230 without the need for a conventional mating optical connector. Forinstance, FIG. 4 shows the lensed flexible optical circuit 250 of FIG. 3incorporated into an optical cassette 200. Cables 103, 105 (or any otheroptical components that are to be optically interconnected through thelensed flexible optical circuit 250) may be terminated with conventionalconnectors 107, 109. These connectors 107, 109 may be plugged intoadapters 115 on the cassette 200 adjacent the respective lenses 230 andoptically couple with the lenses 230 (and, through the lenses, with thefibers 217 of the flexible optical circuit 250) without the need for aconventional, complementary mating receptacle connector on the inside ofthe cassette housing 201.

In yet other embodiments, such as illustrated in FIG. 5 (only thehousing is shown), the entire housing 801 or at least the side walls803, 804, 805, 806 (i.e., the walls interconnecting the panels 807 and808 that bear the apertures 809, 810 that receive the externalconnectors) may be made of a flexible material such as rubber so thatthe housing 801 can be bent to accommodate situations in which theoptical components to be interconnected by the device cannot belongitudinally aligned.

FIG. 6 illustrates yet a further embodiment in which the lensed flexibleoptical circuit 901 includes a housing 900 that comprises hinged members902, 904. Specifically, the housing comprises two housing pieces 902,904 joined at a hinge 905 so that the two housing pieces 902, 904 may bedisposed relative to each other at different angular orientations aboutthe hinge 905. The two lens blocks may be disposed on the opposing endfaces 911, 912 of the housing 902. However, the illustrated embodimentshows a more adaptable configuration that further includes an additionalpanel 907 connected to housing piece 904 via a second hinge 908. Thelens block 909 is mounted on the panel 907, which can be pivoted abouthinge 908 to provide additional freedom in positioning the ends of theflexible optical circuit relative to each other.

Situations in which lensed flexible optical circuits are useful arebountiful. For instance, because there are no internal connectors (inlensed embodiments), the flexible optical circuit interconnector can bemade very thin. Particularly, it may comprise a housing that, other thanthe end faces that receive the external connectors, merely need be thickenough to house the flexible optical circuit (and accommodate anynecessary curvature thereof, such as corrugations or an S curve asmentioned previously). In fact, also as previously noted, in someembodiments, there may be no housing at all and adapters or otherstructure for receiving the external connectors may be incorporateddirectly on the flexible optical circuit adjacent the end faces of thefibers and the lenses. Accordingly, it can be used for very low profilesurface-mounted boxes, such as for use in low profile wall-mountedinterconnects for office buildings, etc. It also may be used forinterconnects in modular furniture pieces, which often provide verysmall spaces for electrical or optical equipment.

Yet further, it is envisioned that a wide variety of opticalinterconnects can be made modularly from a relatively small number ofmodularly connectable housing components, flexible optical circuits,lens blocks, and adapters. Particularly, there would need to be aflexible optical circuit for each different optical routing patterntype, e.g., 1 to 12 cable breakout (such as illustrated in FIG. 3),shuffle (such as illustrated in FIG. 1), 1 to 4 breakout, 1 to 4 opticalsplitter, etc. However, note that a single lensed flexible opticalcircuit may be used for various different numbers of breakouts, splits,shuffles, etc. For instance, a lensed flexible optical circuit inaccordance with the present invention bearing fiber routing for ten 1 to4 breakouts may be used to create an optical cassette to provideanywhere from a single 1 to 4 breakout to as many as ten 1 to 4breakouts. If the situation calls for less than ten such breakouts, thensome of the fibers/lenses simply would not be used.

While the optical interconnects have been described herein in connectionwith embodiments employing molded lenses, it will be understood thatthis is merely exemplary and that other optical components may beembedded in the laminate at the ends of the fibers, such as diffractiongratings, Escalier gratings, mirrors, and holograms.

Since the lensed flexible optical circuits are flexible, they can bebent to accommodate many different physical layouts. Furthermore, thelensed flexible optical circuits may be constructed of sufficient lengthto accommodate longer applications, but may be folded for shorterapplications. In cassette type or other application involving a housing,a set of multiple housing pieces adapted to be modularly joined to eachother in various combinations may be provided. The housing componentsmay provide for hinged and/or fixed joining. One or more of the housingcomponents may be flexible. Thus, it is possible to modularly create awide variety of housing shapes, place one of the flexible opticalcircuits within it, and place lens blocks in suitable adapters disposedin windows in the housings.

Since the lensed (FIG. 3) and unlensed (FIGS. 1 and 2) flexible opticalcircuits discussed hereinabove contain optical fibers, they can be benttoo sharply so as to cause breakage of the fibers or at least signalloss. Delamination of the flexible optical circuit also is possible ifbent too sharply. In order to limit bending of the flexible opticalcircuits, a bend limiting layer may be added to the laminate. FIG. 7 isa bottom perspective view of a lensed flexible optical circuit 250adapted to perform the same functions as the 8-to-8 shuffle of FIGS. 1and 2, except employing a lensed flexible optical circuit such as inFIG. 3, rather than an unlensed flexible optical circuit andconventional internal connectors as in FIGS. 1 and 2. FIGS. 8A and 8Bare cross-sectional views through 5 sections 8A-8A and 8B-8B,respectively, in FIG. 7. In the illustrated embodiment, the bendlimiting layer 333 comprises a plurality of blocks 335 coupled to eachother via a flexible film 337. The blocks 335 are spaced from each otherand sized so that the layer 333 may freely bend to the point at whichthe blocks 335 contact each other at their corners in order to preventfurther bending of the film, as illustrated in region 340 in FIG. 9.More specifically, adjacent pairs of blocks contact each other at theircorners when a predetermined bend radius is reached, thereby resistingfurther bending of the bend limiting layer and, thereby, the flexibleoptical substrate to which it is laminated. The bend limiting layershould be attached to one of the major surfaces of the flexible opticalcircuit so as to bend with and substantially identically to the flexibleoptical circuit substrate, which can be achieved, for instance, byadhering or otherwise attaching it to the flexible optical circuitsubstrate substantially over the bend limiting layer's entire extent.

The spacing and size of the blocks should be selected so as to preventfurther flexing of the flexible optical circuit 250 when the bend radiusof the film is slightly less than the maximum desired bend radius toprevent delamination, fiber breakage, and/or signal loss within thefibers. The blocks may be hard or may have some resilience in order toprovide a soft bend limiting stop.

By providing a single, two-dimensional planar array of blocks (e.g.,rows and columns), bending is limited in two directions, namely, thedirections illustrated by arrow pairs A and B in FIGS. 8A and 8B. Morespecifically, the spacing of the blocks in direction X combined with theheight of the blocks in dimension Z collectively define the bend limitin direction A, and the spacing of the blocks in dimension Y combinedwith the height of the blocks in the Z dimension collectively define thebend limit in direction B. The blocks theoretically also can be used tolimit bending within the plane of the flexible optical circuit, butflexible optical circuits generally are not sufficiently flexible inthat dimension to be of any concern.

If bend limiting is desired in only one direction, then the plurality ofblocks may comprise a single line of blocks (e.g., a single row orcolumn).

In the bend limiting layer 333 illustrated in FIGS. 7, 8A, and 8B, theblocks 335 extend from the film 337 in only one direction (downwardlyfrom the film 337 in the dimension). However, FIG. 10 shows an alternateembodiment of a bend limiting layer that limits bending in both opposingdirections about the bend axis. Specifically, FIG. 10 is across-sectional side view through an alternate embodiment of a bendlimiting layer 333′ in which the blocks 335′ extend from the film 337′in both directions of the Z dimension, i.e., both above and below theplane defined by the film 337′. This bend limiting layer 333′ limitsbending in both directions about the bend axis (see arrow pairs C andD). If desired for any reason, the bend limit in the two directions ofeach arrow pair can be made different by making the blocks asymmetricabout the plane defined by the film 337 (i.e., having a different heightabove the plane of the film 337 than below the film). In fact, since thebend limiting layer 333 is placed on one side of the flexible opticalcircuit 250, the blocks 335 actually would need to be slightly differentheights above and below the film 337 in order to provide identical bendlimits in both arrow pair directions because the film would stretch whenbent in one direction and compress in the other direction. In otherembodiments, instead of a single block extending through the film inboth directions, different blocks may be disposed on one side of thefilm than on the other side.

Yet further, the blocks 335 can be disposed on one side of the film 337so as to limit bending only in one direction of the arrow pair A and/orarrow pair B. In some embodiments, a first bend limiting layer may bedisposed on one side of the flexible optical circuit and a second bendlimiting layer may be disposed on the other side of the flexible opticalcircuit substrate in order to collectively provide bend limiting in bothdirections of the arrow pair(s).

The blocks need not be uniformly spaced. For example, if for any reasonit is desired to allow a first portion of the flexible optical circuitto bend more than a second portion, the blocks may be spaced furtherapart (and/or made shorter) in the first portion of the bend limitinglayer than in the second portion. Furthermore, the bend limit in the twoorthogonal directions represented by arrow pair A on the one hand andarrow pair B on the other hand need not necessarily be equal. Forexample, the blocks may be spaced at longer intervals in dimension Ythan in dimension X so as to allow greater bending (i.e., bending to asmaller radius) in the direction of arrow pair B than in the directionof arrow pair A. The particular routing of the fibers on the flexibleoptical circuit very well may dictate the ability to allow much greaterbending in one direction or one portion of the flexible optical circuitthan in another. For instance, the flexible optical circuit of FIGS.3-5, in which the fibers run substantially in the X dimension, can beallowed to bend to a much smaller radius in the direction of arrow pairB (i.e., bending about an axis substantially parallel to the fibers)than in the direction of arrow pair A (i.e., bending about an axissubstantially perpendicular to the fibers). This feature could be veryimportant in flexible optical circuits that need to be rolled into acylinder, such as to fit within existing conduit.

Yet further, while the blocks 335 are substantially cubic in theillustrated embodiments, this is merely exemplary. The blocks may be ofessentially any shape, such as cubes, cylinders, semi-cylinders,spheres, hemispheres, rectangular prisms, triangular prisms, truncatedcones (frustums), truncated pyramids, etc. In fact, the shape, and notmerely the size, of the blocks may be used to dictate the bend limit indifferent directions. In addition, the shapes of the blocks may bedifferent in different portions of the flexible optical circuitsubstrate so as to provide different bend limits in different portionsof the flexible optical circuit substrate.

The film layer 337 preferably is formed of a flexible and resilientfilm, such as another layer of Mylar® (a trademark of E.I. DuPont DeNemours and Company) or another flexible and resilient polymer. The filmpreferably is resilient because it may need to stretch and compress soas not to de laminate from the flexible optical circuit during bendingand/or so as not to unnecessarily resist bending in the directionopposite of the side of the flexible optical circuit on which it isdisposed.

The blocks 335 may be either embedded in the film 337, as illustrated,or adhered to one side of the film. In other embodiments, the bendlimiting layer 333 may be of unitary construction, such as a moldedpiece made of a single material such as Mylar® with the block portions335 simply being molded thicker than the intermediate film portions 337.Alternately, the blocks may be formed of any reasonable hard orsemi-hard material, such as polyethylene, hard rubber, metal, etc.

In yet other embodiments, the blocks 335 need not be attached to aseparate film such as film 337, but instead may be adhered to orotherwise disposed directly on one or both of the opposing majorsurfaces 338, 339 of the flexible optical circuit 250 itself.

In embodiments in which the flexible optical circuit 250 is disposedwithin a bendable housing such that the flexible optical circuit onlybends essentially as dictated by the bending of the housing, such as inthe embodiments illustrated in FIGS. 7 and 8, then the bend limitinglayer(s) may be applied to the housing instead of the flexible opticalcircuit. FIG. 11 illustrated such an embodiment. In this embodiment, twobend limiting layers 350, 352 are disposed on opposite sides 803, 805 ofthe flexible housing 801 of FIG. 9.

Having thus described particular embodiments of the invention, variousalterations, modifications, and improvements will readily occur to thoseskilled in the art. Such alterations, modifications, and improvements asare made obvious by this disclosure are intended to be part of thisdescription though not expressly stated herein, and are intended to bewithin the spirit and scope of the invention. Accordingly, the foregoingdescription is by way of example only, and not limiting. The inventionis limited only as defined in the following claims and equivalentsthereto.

What is claimed is:
 1. A device for interconnecting optical signalsbetween at least one first optical component and at least one secondoptical component comprising: a flexible optical circuit substrate layerhaving first and second, opposed major surfaces; a plurality of opticalfibers disposed on the substrate, each of the optical fibers having afirst end and a second end; a bend limiting layer attached to theflexible optical circuit so as to bend with and substantiallyidentically to the flexible optical circuit substrate, the bend limitinglayer comprising a plurality of blocks disposed relative to each othersuch that adjacent pairs of the blocks contact each other when the bendlimiting layer is bent a predetermined amount, thereby resisting furtherbending of the bend limiting layer and the flexible optical circuitsubstrate.
 2. The device of claim 1, wherein the bend limiting layer isattached to the first major surface of the flexible optical circuitsubstrate.
 3. The device of claim 1 further comprising a housing withinwhich the flexible optical circuit substrate is disposed, wherein thebend limiting layer is attached to the housing.
 4. The device of claim 1further comprising: at least a first light-guiding, fiber terminationoptical element disposed on the substrate adjacent the first ends of theoptical fibers positioned to couple light with the optical fibers; andat least a second light-guiding, fiber termination optical elementdisposed on the substrate adjacent the second ends of the optical fiberspositioned to couple light with the optical fibers.
 5. The device ofclaim 1, wherein the light-guiding, fiber termination optical elementsare lenses.
 6. The device of claim 1, wherein the flexible opticalcircuit substrate comprises a laminate having first and second layers,and wherein the plurality of optical fibers are embedded between thefirst and second layers.
 7. The device of claim 1, wherein the bendlimiting layer further comprises a film interconnecting the blocks. 8.The device of claim 7, wherein the film is resiliently stretchable. 9.The device of claim 7, wherein the blocks and the film of the bendlimiting layer are unitary.
 10. The device of claim 7, wherein theblocks extend in only one direction perpendicularly from a plane definedby the film.
 11. The device of claim 1, wherein the bend limiting layercomprises a first bend limiting layer disposed on the first majorsurface of the flexible optical circuit substrate and a second bendlimiting layer disposed on the second major surface of the flexibleoptical circuit substrate.
 12. The device of claim 1 wherein the blocksare arranged in a two dimensional planar array.
 13. The device of claim12 wherein the blocks are arranged in rows and columns.
 14. The deviceof claim 12 wherein the bend limiting layer provides different bendlimits in different orthogonal directions.
 15. The device of claim 3wherein the housing is flexible.
 16. The device of claim 3 wherein thehousing comprises first and second housing parts hingedly connected toeach other.